Application of topographic elevation data generated by remote sensing approaches to flood inundation analysis model

IF 1.9 4区 农林科学 Q2 AGRICULTURAL ENGINEERING
Maulana Ibrahim Rau, Atriyon Julzarika, Natsuki Yoshikawa, Takanori Nagano, Masaomi Kimura, Budi Indra Setiawan, Lan Thanh Ha
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Abstract

High-resolution topographic data are crucial for delta water management, such as hydrological modeling, inland flood routing, etc. Nevertheless, the availability of high-resolution topographic data is often lacking, particularly in low-lying regions in developing countries. This data scarcity poses a significant obstacle to inland flood modeling. However, collecting detailed topographic data is demanding, time-consuming, and costly, making remote sensing techniques a promising solution for developing flood inundation analysis models worldwide. This study presents a novel understanding for utilizing topographical elevations obtained using remote sensing techniques to create a flood inundation analysis model. In a study of three watersheds, Kameda, Niitsu, and Shirone (Japan), the assessment of digital terrain models (DTMs) showed that remote sensing-based DTMs (RS-DTMs) exhibited high reliability of coefficient of determination (R2) and root-mean-square errors, compared with the airborne LiDAR-based topography from the Geospatial Information Authority of Japan. Comparing the flood modeling results from LiDAR data and RS-DTM, with Kameda and Niitsu performing favorable outcomes, Shirone exhibited less accurate results. We hypothesized that this was caused by the topographic distortions due to lack of evenly distributed reference points. Hence, we revised the topography by adjusting both the slope and intercept from the regression equation. This verification successfully showed that the flood inundation volume correlation improved, achieving R2 results for the three watersheds ranging from 0.975 to 0.997 and Nash–Sutcliffe Efficiencies ranging from 0.938 to 0.986 between the resulting flood models based on the LiDAR data and RS-DTM. Based on these findings, we recognized the significance of uniformly distributed geodetic height points. In areas lacking height references, high-precision survey instruments can be employed for achieving uniform distribution.

Abstract Image

将遥感方法生成的地形高程数据应用于洪水淹没分析模型
高分辨率地形数据对三角洲水管理至关重要,如水文模型、内陆洪水路线等。然而,高分辨率地形数据往往缺乏,尤其是在发展中国家的低洼地区。这种数据匮乏对内陆洪水建模造成了巨大障碍。然而,收集详细的地形数据要求高、耗时长、成本高,因此遥感技术成为全球开发洪水淹没分析模型的一个有前途的解决方案。本研究提出了一种利用遥感技术获得的地形高程来创建洪水淹没分析模型的新理解。在对日本龟田、新津和白根三个流域的研究中,对数字地形模型(DTMs)的评估表明,与日本地理空间信息局基于航空激光雷达的地形图相比,基于遥感技术的数字地形模型(RS-DTMs)在判定系数(R2)和均方根误差方面表现出较高的可靠性。比较激光雷达数据和 RS-DTM 的洪水模型结果,龟田和新津的结果较好,而白根的结果则不太准确。我们推测这是由于缺乏均匀分布的参考点导致地形失真造成的。因此,我们通过调整回归方程中的斜率和截距来修正地形。验证结果表明,基于激光雷达数据和 RS-DTM 建立的洪水模型之间的洪水淹没量相关性得到了改善,三个流域的 R2 结果在 0.975 到 0.997 之间,纳什-苏特克利夫效率在 0.938 到 0.986 之间。基于这些发现,我们认识到了均匀分布的大地测量高程点的重要性。在缺乏高程基准的地区,可以使用高精度测量仪器来实现均匀分布。
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来源期刊
Paddy and Water Environment
Paddy and Water Environment AGRICULTURAL ENGINEERING-AGRONOMY
CiteScore
4.70
自引率
4.50%
发文量
36
审稿时长
2 months
期刊介绍: The aim of Paddy and Water Environment is to advance the science and technology of water and environment related disciplines in paddy-farming. The scope includes the paddy-farming related scientific and technological aspects in agricultural engineering such as irrigation and drainage, soil and water conservation, land and water resources management, irrigation facilities and disaster management, paddy multi-functionality, agricultural policy, regional planning, bioenvironmental systems, and ecological conservation and restoration in paddy farming regions.
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